FGFR1 underlies obesity-associated progression of estrogen receptor–positive breast cancer after estrogen deprivation
Elizabeth A. Wellberg, Peter Kabos, Austin E. Gillen, Britta M. Jacobsen, Heather M. Brechbuhl, Stevi J. Johnson, Michael C. Rudolph, Susan M. Edgerton, Ann D. Thor, Steven M. Anderson, Anthony Elias, Xi Kathy Zhou, Neil M. Iyengar, Monica Morrow, Domenick J. Falcone, Omar El-Hely, Andrew J. Dannenberg, Carol A. Sartorius, Paul S. MacLean
Elizabeth A. Wellberg, Peter Kabos, Austin E. Gillen, Britta M. Jacobsen, Heather M. Brechbuhl, Stevi J. Johnson, Michael C. Rudolph, Susan M. Edgerton, Ann D. Thor, Steven M. Anderson, Anthony Elias, Xi Kathy Zhou, Neil M. Iyengar, Monica Morrow, Domenick J. Falcone, Omar El-Hely, Andrew J. Dannenberg, Carol A. Sartorius, Paul S. MacLean
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Research Article Endocrinology Oncology

FGFR1 underlies obesity-associated progression of estrogen receptor–positive breast cancer after estrogen deprivation

Abstract

Obesity increases breast cancer mortality by promoting resistance to therapy. Here, we identified regulatory pathways in estrogen receptor–positive (ER-positive) tumors that were shared between patients with obesity and those with resistance to neoadjuvant aromatase inhibition. Among these was fibroblast growth factor receptor 1 (FGFR1), a known mediator of endocrine therapy resistance. In a preclinical model with patient-derived ER-positive tumors, diet-induced obesity promoted a similar gene expression signature and sustained the growth of FGFR1-overexpressing tumors after estrogen deprivation. Tumor FGFR1 phosphorylation was elevated with obesity and predicted a shorter disease-free and disease-specific survival for patients treated with tamoxifen. In both human and mouse mammary adipose tissue, FGF1 ligand expression was associated with metabolic dysfunction, weight gain, and adipocyte hypertrophy, implicating the impaired response to a positive energy balance in growth factor production within the tumor niche. In conjunction with these studies, we describe a potentially novel graft-competent model that can be used with patient-derived tissue to elucidate factors specific to extrinsic (host) and intrinsic (tumor) tissue that are critical for obesity-associated tumor promotion. Taken together, we demonstrate that obesity and excess energy establish a tumor environment with features of endocrine therapy resistance and identify a role for ligand-dependent FGFR1 signaling in obesity-associated breast cancer progression.

Authors

Elizabeth A. Wellberg, Peter Kabos, Austin E. Gillen, Britta M. Jacobsen, Heather M. Brechbuhl, Stevi J. Johnson, Michael C. Rudolph, Susan M. Edgerton, Ann D. Thor, Steven M. Anderson, Anthony Elias, Xi Kathy Zhou, Neil M. Iyengar, Monica Morrow, Domenick J. Falcone, Omar El-Hely, Andrew J. Dannenberg, Carol A. Sartorius, Paul S. MacLean

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Figure 1

FGFR1 activation associates with obesity and a poor response to endocrine therapy.

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FGFR1 activation associates with obesity and a poor response to endocrin...
(A) Venn diagram of unique and shared activated regulatory pathways between tumors from those who did not respond to letrozole (Nonresponders, blue, n = 57 pathways), those who did respond (Responders, green, n = 86 pathways), and estrogen receptor–positive (ER-positive) tumors from women with elevated BMI (red, n = 83 pathways). (B) Z scores of activated upstream regulators reported by Ingenuity to be common to nonresponders and patients with elevated BMI (P < 0.05). (C) Representative images of primary human breast tumors stained for pFGFR1. Top panel, negative tumor (0% positive); bottom panel, > 75% positive. Magnification, 20×. (D) Kaplan Meier survival curves showing disease-free (left) and breast cancer–specific (right) survival in patients based on pFGFR1 staining. n = 39, <75% positive; n = 7, ≥75% positive.